AU621668B2

AU621668B2 - Novel microorganism and use thereof in ripening cheese

Info

Publication number: AU621668B2
Application number: AU42579/89A
Authority: AU
Inventors: Tadgh Callanain
Original assignee: Agricultural Genetics Co Ltd
Current assignee: MicroBio Group Ltd
Priority date: 1988-10-05
Filing date: 1989-10-05
Publication date: 1992-03-19
Anticipated expiration: 2009-10-05
Also published as: EP0365173B1; DK489089D0; ATE94343T1; DK489089A; NZ230911A; AU4257989A; DE68909165D1; EP0365173A1; GB8823429D0; US4976975A; CA2000216A1

Abstract

The invention relates to Lactobacillus helveticus AGC1, a sample of which has been deposited on 29 September 1988 at The National Collections Of Industrial And Marine Bacteria Limited under the accession number NCIB 40051, or a mutant or derivative thereof. This strain is useful as part of a starter culture addition to cheese milk, for accelerated ripening of cheddar style cheeses.

Description

-7r COMMONWEALTH OF AUSf PATENTS ACT 1952 U CO TE SPECIFICATION NAME ADDRESS OF APPLICANT: Agricultural Genetics Company Limited Unit 154/155, Cambridge Science Park Milton Road Cambridge CB4 4BH United Kingdom NAME(S) OF INVENTOR(S): Tadgh CALLANAIN ADDRESS FOR SERVICE: DAVIES COLLISON Patent Attorneys 1 Little Collins Street, Melbourne, 3000.

COMPLETE SPECIFICATION FOR THE INVENTION ENTTTLED: Novel microorganism and use thereof in ripening cheese The following statement is a full description of this invention, including the best method of performing it known to me/us:i: c 1 la- This invention relates to a novel microorganism and its use in a method for the accelerated ripening of hard type cheeses of the Cheddar and related variant types, including low fat cheddar style cheese.

After initial manufacture, Chcldar cheese and Cheddar style varieties of cheese require a storage period of the order of four to six months at about 70C, prior to sale This storage period is necessary to allow the body of the cheese to acquire the typical characteristics of Cheddar cheese in terms of texture, consistency, and flavour. This extended storage period has evident disadvantages with respect to the financing costs of the cheese stocks involved, and with respect to marketing and production planning.

fl#6 *a tt CE C C C C I d i t' The development of typical Cheddar cheese, body, texture and flavour is the end result of complex physical and biochemical processes. These processes are influenced by a wide range of factors such as the composition and bacterial flora of the raw milk, the hygienic and manufacturing conditions used, the *ype of and condition of the starter bacteria used and the type of adventitious organisms present in the finished cheese. The composition of the cheese produced, the length of ripening period, and the temperature of storage during the ripening period are also important with respect to the development of a typical Cheddar cheese texture and flavour.

It is recognised that the body of the cheese is mainly modified from the initial 'curdy' texture and appearance of freshly produced cheddar cheese to that of a typical cheese as purchased by the consumer, by the proteolytic action of retained chymosin, by the proteolytic and peptidase enzymes, produced by the lactic acid starter bacteria and by adventitious organisms. These adventitious non-starter bacteria form the major tl.ra of cheddar cheese after a )m 8'31 a 1 1 -2relatively short period of ripenning. The influence and interrelationships of these factors, in terms of cheese flavour and cheese texture, are as yet relatively undefined.

Manufacture of low fat cheeses presents problems in that flavour development is extremely slow and consequently such cheeses have a low consumer appeal.

A number of attempts to accelerate the flavour development of Cheddar and low fat Cheddar-style cheeses have been described.

EP-A-0150743 describes a method for accelerating the ageing process of Cheddar style cheese which is based on the use of preserved, partially disrupted preparation of the lactic acid 0o. bacterium Lactobacillus caesi, Lactobacillus lactis, Lactobacillus plantarum and a blend of pre-gastric lipases.

WO 82/03971 describes a method for the production of a low fat cheese product with enhanced flavour, using a culture of Lactobacillus bulcaricus and Streptococcus thermophilus and with a culture of Lactobacillus caesi, in addition to a normal cheese starter.

g A number of methods to achieve accelerated ripening of Cheddar style cheeses, mainly based on enzyme additions are now commercially available or publicised (refs: 1,4,5,6).

4 However, one of the disadvantages of some of the systems is that the enzyme preparation has to be added to the cheese curd during the salt addition process and can give rise to enzyme distribution problems in the finished cheese, potentially Sresulting in flavour variations and physical defects such as cheese mottling. In the United Kingdom these systems have an additional disadvantage in that enzyme additions, other than coagulating enzymes, are not permitted under current cheese regulations, in traditional English type cheeses manufacture for direct sale to the consumer.

*U ibl i -3- EP-A-0150743 suffers from the disadvantage that cells of the lactic acid bacteria must be partially disrupted and then preserved before use. Such a process is technically difficult to operate and adds to the cost of cheese manufacture. WO 82/03971 suffers from the disadvantage that three cultures, in addition to a normal cheese starter, must be used.

The present invention relates to the surprising discovery that addition of a specific culture of Lactobacillus helveticus AGC1, characterised by its carbohydrate utilisation pattern, and by its content of the nucleotides, guanine and cytosine to a typical manufacturing T process for Cheddar and low fat Cheddar-style cheeses t.

Sa 15 results in accelerated ripening.

a't The invention thus provides Lactobacillus helveticus AGC1, i c c which has been deposited on 29 September 1988 at The National Collections of Industrial and Marine Bacteria Ltd (NCIMB), P.O. Box 31, 135 Abbey Road, Aberdeen AB9 8DG, UK, under accession number NC1B 40051, or a mutant or derivative thereof which is functionally equivalent to S" strain AGC1.

L.helveticus AGC1 can be distinguished from other strains of L.helveticus by its characteristic carbohydrate utilisation pattern (see Table Thus, the invention provides a novel strain of L. helveticus which can be used to accelerate ripening of Cheddar style cheeses.

In practice, the additional culture is added at the normal point of starter culture addition to cheese milk, during the cheese making process. The rate of culture addition can be varied as required and is normally in the range of 0.05 911216,jnsac.015.42579.res3 3A- The addition of L. helveticus AG'C1 in this mnanner may be regearded as the deliberate addition of a~ non-traditional (in this application) lactic acid starter bacterium, as a source of additional peptidases and prote,,lytic enzymes.

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911216,jmscznc.015.42579.res,3 4 produces the correct amount and type of breakdown in the body of the cheese, as determined by an expert cheese grader, and confirmed rheologically by means of measurements using an Instron universal tester instrument.

Novel aspects of our invention include the following: 1. A method for producing Cheddar cheese or Cheddar-like cheeses of composition in the range of 20-38% fat content and 30-45% moisture content made in a usual Cheddar cheese manufacturing type operation, with the specific addition of the identified strain of Lactobacillus helveticus AGC1 in addition to the usual cheese starter culture organisms.

Such a method results in a cheese characterised by an accelerated ripening profile and in which unacceptable changes in texture do not occur.

e 2. A method for the production of a low fat Cheddar style cheese with a fat content in the range 8 20% and a moisture content in the range of 37 54% made with the specified strain of Lactobacillus helveticus AGC1, in addition to the usual cheese starter culture organisms.

Such a method results in a cheese characterised by an 4o accelerated ripening profile and in which unacceptable changes in texture do not occur.

t e L. helveticus AGC1 is a thermophilic strain and has an optimum temperature for growth that is higher than that of normal starter cultures. For that reason it is important that the nubation tmpraur 'ripening' is maintained in the range of 94--108 0 F .4--442.20C). Within this temperature range growth of all the starter cultures is maintained in balance. At higher temperatures L.helveticus AGC1 will overrun traditional cultures resulting in a poor quality cheese.

The application of the invention is exemplified in the following Examples.

-1- I A o P AI ,4.

1 1 5 Example 1 Typical Cheddar Cheese Manufacturing Schedule, with the addition of Lactobacillus helveticus AGCl Raw Materials A. Milk which should be clean fresh and free from off flavour, antibiotics or any other inhibitory substance and be of good bacteriological quality.

B. Starters lactic cultures Normal S. lactis/S. cremoris type.

and (ii) L. helveticus AGC1 o C. Rennet oo Standard rennet, as necessary ria a 4 S D. Anatto Coloured variety only.

E. Salt Standard cheese salt.

va 0 0 0 PROCESSING CONDITIONS A Blend of normal starter cultures and the L. helveticus AGC1 culture, depending on the activity of the cultures and the type of acid profile required, is added at the rate of The L. helveticus AGC1 culture is added at the rate of 0.05-1%.

Both cultures are added simultaneously at the beginning of the usual milk 'ripening' period, immediately prior to renneting.

SThe scald temperature should be sufficiently high to promote growth of the L. helveticus AGC1 culture (ie. in the range of .9lo~108F (-42.2 0 Temperatures outside this range may result in an excessive outgrowth of the L. helveticus AGC1 culture. No significant difference from control cheese should be noted in the rennet to mill time.

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6 Salt addition must be targeted to give a salt level in the finished cheese of The uniformity of salt distribution is of prime importance. The culture will be inhibited by a high salt concentration, thereby nullifying the effect of accelerated ripening. The cheese is thereafter pressed and transferred to storage as per routine procedures.

Typical results are shown as compared to the control cheese, in Table 2, demonstrating the initial rapid textural change in cheese produced by the method of this application, as compared to the control sample. This process also results in the production of the appropriate level and type of proteinases and e 4 S peptidases which, with the retained chysmosin, are responsible o for the breakdown of the initial cheese body and the production of a typical body texture and flavour profile, or the precursor chemicals to produce characteristic Cheddar cheese flavour, o body and texture.

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C8 0 Ce One of the traditional flavour defects in Cheddar cheese is a "bitr" flavour, which is thought to be due to the production txo oic of peptides due to insufficient hydrolysis of the peptide chains. Our process appears to result in the rapid breakdown of peptides, in excess of that encountered in a control sample, with the production of greater amounts of single amino-acids, without the production of bitter 'off' flavours. An amino acid analysis of trichloroacetic acid (TCA) extracts of Control and Accelerated cheeses at various time intervals is given in Table 3.

We believe that the mode of action of the L. helvecicus AGCl culture is effectively the production of proteolytic and peptidase enzymes of the right quantity, type and character resulting in rapid breakdown of the protein structure to give the required texture, accompanied by extensive peptide hydrolysis, resulting in the production of a correct blend of amino acids, peptides, lipases, fatty acids, etc. which act as either the main flavour ingredient in cheese or the precursor 7 such flavour development. Our process produces a cheese ;which is ready for pre-packing or sale to consumer or customers in approximately 8 to 10 weeks, as shown in Table 2, as compared to sixteen to twenty weeks for cheese produced using standard techniques.

A typical comparison of the ageing process for an accelerated Cheddar cheese, as compared to a control Cheddar cheese, is given in Table 2. In addition, surprisingly, we have noted that whereas flavour development continues at an accelerated rate, the texture changes in cheese produced by our method effectively reach a plateau for an indefinite period. In other words, once the initial texture changes are completed, evident, continuing unacceptable changes in texture do not occur, thus avoiding the production of an unacceptable product at any point in the life of the cheese.

Example 2: Production of Low Fat Hard Type Cheese To produce low fat cheese using L. helveticus AGC1, particular attention needs to be given to certain key areas: o s o o ot o 00r o o t *r .I tr 'sotc 0000 0 0* 1 0 *r 5 a 0 .00, 0 o 1 0 0 oo*'00 0 *r S 0o* 0 0 Standardisation of the cheese milk and its heat treatment.

The blending and addition of the lactic cultures.

Setting and cutting of the curd.

Scalding, stirring and pitching the curd.

Curd treatment or cheddaring.

Salting.

Pressing.

Fresh raw milk needs to be standardised, by the addition of skim milk or by partial separation to a given fat percentage, or fat to protein ratio.

The fat levels will depend upon: 1. Fat required in the end product.

2. Fat lost in the whey, or conversely, fat retained in the cheese.

3. Protein retained in the cheese.

8 For most factory conditions, the fat in the cheese will probably be less than 17% fat, therefore a fat to protein ratio of the order of 1:2, is required.

The fat reduced milk is pasteurised at 161-62°F (71.7-72.2 0

C)

and cooled to 88 0 F (31.1 0 C) for incubation.

A blend of cultures is added to the vat milk and this consists of the normal cultures of the day and L. helveticus AGC1. The amount of culture and the ratio between cultures is governed by: 1. Acid development required to give the correct Rennet to Mill time (normally 3 hours 20 minutes to 3 hours minutes) S2. Rate of maturation required.

At ripening temperature of 88 0 F (31.1 0 C) significant acidity development from the L. helveticus AGC1 cultures is not expected, or encountered. Too high ripening temperatures will S result in the L. helveticus AGC1 culture outgrowing the normal S culture, and over maturation of the resulting cheese.

it Starter addition mix needs to be in the order of 1-2% and the L.helveticus AGC1 being added at 5-15% of the total inoculum.

c The length of ripening influences the moisture 4 n -r.tae properties of the curd and at least 35-45 minutes is required.

Acidity at the end of the period is normally in the range 0.16- 0.19% lactic acid.

At the end of ripening, standard rennet is added at the rate of oz per 1000 gallons (0.249 g/l) of cheese milk.

The cheese milk is allowed to settle for approximately minutes, or until the curd is firm. The exact cutting operation will vary from plant to plant, but the aim is to cut r U l T f 9 the curd fairly large, so as to retain as much moisture as possible. The stirring of the curd should be as gentle as possible, but obviously sufficient to prevent the curd matting at the bottom of the vat.

Scald temperatures ranging from 94-96 0 F (34.4-35.6 0 C) are used.

The curd is milled with a Cheddar chip mill at an acidity of 0.55% lactic acid.

Salt addition is targeted to give approximately 1.4-1.5% salt in the finished cheese. Under salting may result in rapid proteolysis with bitter off flavour, whereas over salting will give cheese of poor texture and sweeter flavours. The cheese S. is pressed following standard cheese pressing procedures.

j Typical recipes for production of conventional low fat Cheddar Scheeses and for production of low fat Cheddar cheeses using L.

helveticus AGC1 are given in Table 4. A typical comparison of the ageing process for an accelerated low fat Cheddar cheese, S as compared to a conventional low fat Cheddar cheese, is given in Table 5. Cheese produced by our method develops a mature a 41 S flavour by 7 weeks whereas conventional low fat cheese does not S reach this level of flavour development unless stored for Sunrealistic periods greater than 18 weeks). In addition, S surprisingly, low fat cheeses produced by our method do not S undergo any unacceptable changes in texture.

REFERENCES

1 i. ARBIGE M.V. et al Novel Lipases for Cheddar Cheese Flavour Development Food Technology 91-98, April 1986 2. DAVIS F.L. AND LAW B.L. (Editors) Advances in the Microbiology and Biochemistry of Cheese and Fermented Milks.

Elsevier Applied Science Publishers. Pages 209-227 ii -i i, I 10 10 3. GRAPPIN R. et al Primary Proteolysis of Cheese Proteins during Ripening. A Review.

Journal of Dairy Science 68, 531-540, 1985.

4. LAW B.A.

Accelerated Ripening of Cheddar Cheese with Microbial Proteinases.

Netherlands Milk and Dairy Journal 35 313-327, 1981.

LAVERY AND SON PROPRIETARY LTD. WO 82/03971 o 0 0 eo 0 6. MILES LABORATORIES, INC. EP-A-0150 743 00 00 1 7. THOMAS, T.D.

Oxidate Activity of Bacteria from Cheddar Cheese.

New Zealand Journal of Dairy Science and Technology 21, 37-47, 1986.

8. RANK, T.C. et al O000 0'0 Secondary Proteolysis of Cheese During Ripening.

0 Journal of Dairy Science 68, 801-805, 1985.

0 a a e e

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r R 11 TARE 1 FlE4FJAT~HT( (IF RDC ~RAY]FES BP L ~OBIWC[LU SE ZES Carbon Source Fermentation Activity (3 high, 2 medium, 1 low, 0 negative) AGC1 NCDO NCDO NCDO NCIDO NC NCDO AICC ATCC ATCC* H3 H6 H13 H17 28 30 39538 39539 39542 'ii.

ii ii t C it I Glucose mannos e lactose galactose fructose n-acetyl glucosamnine ribos e trehalos e maltose sucrose adonitol mannitol s orbitol inulin turanose lyxose sorbose rhamnos e methyl -glucoside amygdali n arbutin es culin cellobiose melibiose melezitose raffinose starch xylitol gentiobiose tagatose fucose arabitol gluconate keto-gluconate 1 I t i

I

i it ALL TESTS NEGATIVE Morphologically dissimilar from LBI Not tested Based on readings 24h after incubation at 37CC NCDO type cultures were all L. helveticus strains ATCC 39538 was L. lactis strain ATOC 39538 was L. casei strain ATCC 39542 was L. plantarum strain :i

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1 i i -ii3 i -ii~ 12 TABLE 2 TYPICAL AGEING PROFILE FOR ACCELERATED AS COMPARED TO CONVENTIONAL CHEDDAR CHEESE AGE OF CHEESE GRADING/COMMENTS VAT 9 (CONTROL) VAT 10 (ACCELERATED) 3 weeks Typical young curd Insipid Good body and texture similar to 8-9 week cheese 7 weeks Good body texture Mild Good body and texture, breaking down very nicely similar to 4-5 month Cheddar Good body and texture, on par with 5-6 month Cheddar 9 weekss Good body texture Mild r 'I ai i: Ir *ao 9 9' 0 P

IY

weeks Good body texture Similar to a good 5-6 Mild month Cheddar 12 weeks Typical gocd 3 month good body and texture old Cheddar equal to 6 month old 16 weeks Good cheese 3-4 Good body and texture month age close and smooth, equal to 6 months old 18 weeks Good 4-5 month Equal to 6 month old Cheddar weeks Good body and texture Good body and texture Reasonable flavour, Close and smooth waxy, equal to 5 month 7-8 month old Cheddar 22 weeks Good body and texture Good body and texture Reasonable flavour Close and smooth waxy Equal to 5 month 7-8 month old.

Cheddar GRADING AT 11 WEEKS OLD (NACPE POINTS) VAT 9 VAT Flavour 40 ody Texture 33 33 Colour 9 Finish 5 87 points 88 points

L.

i -~lana~-~-Dar~ 13 TABLE 3 OX1(PAREN OF Wia SCKUBLE MItIM ACEIDS IN CXNTJ AM AC1I LERXID CIEDES WITI TIE Nao Mbles/per il of sample TIME 20 aays 20 days 84 days 89 days 172 days 172 days Control Accel. Control Accel. Control Accel.

Taurine 000 Urea Asp 40 45 44 190 79 300 Thxre 9. 1 17 4 69 29 140 Ser 12 21 A1 98 18 120 bf O 00 Asn 00 Glu 87 140 130 610 240 980 Gin Sarcosine 0-amino adipic Pro Gly 11 22 14 105 31 170 Ala 24 70 26 134 49 190 Citruiline 3. 9 37 0000 B-aminobutyric Val 20 41 39 220 80 360 *00 Cystine Met 2. 4 2. 0 11 46 23 0 Cystathionine Ileu 4. 2 15 8. 9 120 20 250 Leu 55 78 94 370 190 530 Tyr 7. 7 13 9. 2 70 11 110 Phe 30 41 52 170 100 250 S. p-amino butyric acid 6 -alanine 6 -amino butyric acid Ornithine 3. 5 0. 5 25 3. 1 58 63 Lys 41 94 55 370 110 610 Tryp is 7. 0 15 8. 4 83 14 170 1-Me-His 3-Me-His Arg 23 46 18 170 22 120 not determined r

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14 TABLE 41 LOW FAT CHEDDAR CHEESE RECIPES O000 o a 0 Ot 00 0 0 a @o o a A '0 o a o oR 8 00 o* 0 0 0 000 0 a CONVENTIONAL ACCELERATED MILK 1100 gallons 1100 gallons Fat 1. 62% these will 1. 62% these will Protein 3.20% vary 3. 20% vary STARTER/S Starter of the Starter of the day but reduced day reduced by by 10% of normal of normal rate.

rate.

Acidity: 1.58% LA Acidity: 1. 58% LA 2 gallons of LT. helveticus AGC1 culture.

Acidity: 1. 50% LA rIPENING TEMP. 90OF RIPENING TIME 30 mins 30 mins RENNET 43 oz 43 oz SETTING TIME 45 mins 45 mins CUTTING SPEED Speed 8 for 8 mins Speed 8 for 8 mins (large cut) ,large cut) SCALD TEMP. 92 0 F 96 0

F

(Acidity: 0. 12% LA) (Acidity 0. 12" LA) Scald up in 20 mins Scald up in 20 mins (Acidity: 0. 125% LA) (Acidity: 0. 125% LA) PITCHED 10 minutes after 10 minutes after scald up scald up WHEY OFF 15 minutes 15 minutes (Acidity: 0. 15% LA) (Acidity: 0. 16% LA) ACID DEVELOPMENT 2 hrs 0. 18% LA 2 hrs 10 mins 0. 21% LA (Time from Renneting) 2. 5 hrs 0.27% LA 2 hrs 40 mins 0. 27% LA 3 hrs 0. 35% LA 3 hrs 20 mins 0.45% LA 3. 5 hrs 0.49% LA 3 hrs 50 mins 0. 55% LA 3 hrs 50 mins 0. 57% LA MILLED 0.57% LA 0. 55% LA 15 TABLE 5 TYPICAL AGEING PROFILE FOR ACCELERATED AS COMPARED TO CONVENTIONAL LOW FAT CHEDDAR CHEESE AGE OF CHEESE GRADING/COMMENTS CONVENTIONAL ACCCELERATED (NORMAL STARTER) (NORMAL STARTER L. HELVETICUS AGC1) g *L S

II

ItC 3 weeks Good body and texture Good body and texture Mild flavour Clean, good flavour, more flavour than conventional 4 weeks Good body and texture Good body and texture Clean, mild flavour Good, clean flavour 6 weeks Good body and texture Good body and texture Clean, mild flavour Good, clean, well developed flavour 7 weeks Good body and texture Good body and texture Clean, mild flavour Good, clean, mature flavour 11 weeks Good body and texture Good body and texture Clean flavour Good, clean mature flavour 18 weeks Good body and texture Good body and texture Clean and slightly Good mature flavour sweet e i

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Claims

1. Lactobacillus helveticus AGC1, which has been deposited on 29 September, 1988 at The National Collections of Industrial and Marine Bacteria Limited under the accession number NCIB 40051, or a mutant or derivative thereof which is functionally equivalent to strain AGC1.

2. A method of making cheddar style cheeses, which comprises adding to milk a mixture of starter cultures which includes Lactobacillus helveticus AGC1 (NCIB 40051); allowing the milk to ripen; adding rennet to the ripened milk; allowing the resulting milk to set and form a curd; cutting the curd, stirring and heating to scald temperature; separating the curd from the whey; cheddaring Sthe curd; and then milling the curd, adding salt, pressing and allowing to mature.

3. A method according to claim 2, in which the cheese has a fat content of i20-38% and a moisture content of 30-45%. t00s:

4. A method according to claim 2, in which the cheese has S.a fat content of 8-20% and a moisture content of 37-54%. i"

5. A method according to any of Claims 2 to 4, in which I: Lactobacillus helveticus AGC1 is added in a proportion of 0.05-0.5%, based on the total weight of the starting milk.

6. A method according to any of Claims 2 to 5, in which the scald temperature is in the range of 94 to 108°F.

7. A cheddar style cheese ripened with Lactobacillus helveticus AGC1. ,JCi9 +0051 i V7 4 911216,jmsc.015.42579.res,16 Y 0o^ -17-

8. Cheddar style cheese or a method for its manufacture, substantially as hereinbefo~.e described with reference to the Examples. Dated this 16th day of December, 1991. AGRICULTURAL GENETICS COMPANY LIMITED By Davies Collison Cave Patent Attorneys for the applicant(s) Vt V Sr St V 2 *tt V Vt VA slit *SC LV? IC Vt S C I V SC V I V it V V V Vt I 91126,jnsanc.015.42579.res,17